Radiofrequency particle separator

ABSTRACT

A method of separating a mineral bearing particle from a fluid includes providing a housing along a surface of the fluid, moving the housing along the surface of the fluid with a driver, and applying a radio-frequency electromagnetic field to the fluid with a generator. Applying the radio-frequency electromagnetic field includes increasing a temperature of the mineral bearing particle contained within the fluid to a boiling point of the fluid whereby the mineral bearing particle transfers heat into the fluid.

CROSS-REFERENCE TO RELATED PATENT APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.13/651,102, titled “Radiofrequency Particle Separator,” and filed Oct.12, 2012, the entire disclosure of which is incorporated herein byreference in its entirety for any and all purposes.

BACKGROUND

Mining operations remove aggregate ore from an in-ground deposit andprocess the loose aggregate ore to remove metals, coal, and otherminerals. Ore removed from the ground includes particles of the targetmaterial but may also include various other, secondary materials. Suchsecondary materials may include rock, soil, and other minerals. In orderto produce a pure sample of the target material, the secondary materialmust be removed from the target material sample.

Traditional methods for removing secondary material from a targetmaterial involve a chemical process and one or more finishing steps. Thefinishing steps often fail to fully remove the secondary material fromthe target material. By way of example, finishing steps may include thesize or weight dependent processes of frothing, filtering, and panning.Frothing uses chemicals and large bubbles to chemically separate targetmaterial. Filtering machines rely on a fluid containing the targetmaterial and secondary material and pass the fluid through one or morefilters. The filters are generally fibrous and vary in precision fromcourse to fine. After the fluid is passed through, particles of the samesize are trapped within the filter regardless of whether the particlesare target material or secondary material. Given the need for a puretarget material final product, trapped filter material may be thereafterpanned. While panning separates target material from secondary material,panning is very time consuming. Despite these deficiencies, frothing,filtering and panning remain the primary methods used for removingtarget material from a fluid containing target material and secondarymaterials.

SUMMARY

One method relates to a method of separating a mineral bearing particlefrom a fluid. The method includes providing a housing along a surface ofthe fluid, moving the housing along the surface of the fluid with adriver, and applying a radio-frequency electromagnetic field to thefluid with a generator. Applying the radio-frequency electromagneticfield includes increasing a temperature of the mineral bearing particlecontained within the fluid to a boiling point of the fluid whereby themineral bearing particle transfers heat into the fluid.

Another embodiment relates to a method for separating a mineral bearingparticle from a fluid. The method includes providing a housing,containing the fluid within the housing, the fluid containing themineral bearing particle, applying a radio-frequency electromagneticfield to the mineral bearing particle using a generator, and increasingthe temperature of a portion of the mineral bearing particle with theradio-frequency electromagnetic field. The mineral bearing particletransfers heat into the fluid, and the heated fluid imposesmotion-inducing forces on the mineral bearing particle.

Still another embodiment relates to a method for separating a mineralbearing particle from a fluid. The method includes providing a housing,containing the fluid within the housing, the fluid containing themineral bearing particle, applying a non-uniform radio-frequency fieldto the mineral bearing particle using a generator, and moving themineral bearing particle within the fluid with a propulsion forceinduced by the non-uniform radio-frequency field.

The invention is capable of other embodiments and of being carried outin various ways. Alternative exemplary embodiments relate to otherfeatures an combinations of features as may be generally recited in theclaims.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will become more fully understood from the followingdetailed description taken in conjunction with the accompanying drawingswherein like reference numerals refer to like elements, in which.

FIG. 1 is a schematic view of a generator and fluid in a RF particleseparator.

FIG. 2 is a schematic view of a generator operating upon a fluid in a RFparticle separator.

FIG. 3 is a schematic view of a generator operating upon a fluid withina chute.

FIG. 4 is a schematic view of a target and secondary particle affectedby a field.

FIG. 5 is a schematic view of a target and secondary particle affectedby a field.

FIG. 6 is a schematic view of a target particle affected by a field andheated to a specified skin depth.

FIG. 7 is a schematic view of a target particle affected by a field andheated to a specified temperature gradient.

FIG. 8 is a schematic view of a target particle affected by a field andincluding an induced force component.

FIG. 9 is a schematic view of an RF particle separator having acharacteristic altering system.

FIG. 10 is a schematic view of an RF particle separator having acharacteristic altering system.

FIG. 11 is a schematic view of an RF particle separator having adispenser system.

FIG. 12 is a schematic view of a mobile RF particle separator.

DETAILED DESCRIPTION

Before turning to the figures, which illustrate the exemplaryembodiments in detail, it should be understood that the application isnot limited to the details or methodology set forth in the descriptionor illustrated in the figures. It should also be understood that theterminology is for the purpose of description only and should not beregarded as limiting.

RF separators are intended to provide an efficient replacement totraditional separation equipment. Such RF separators receive a fluidcontaining particles largely separated from rock through polymerizationand raise the temperature of target material to raise the particleswithin a fluid. Such target particles may also be raised magnetically.Various conditions are controlled to ensure that secondary material isnot raised within the fluid. The RF separators produce a final productof target material containing little, if any, secondary material.

Referring to the exemplary embodiment shown in FIGS. 1-2, a particleextractor is shown as radiofrequency (RF) particle separator 10. RFparticle separator 10 extracts materials without relying on filtering orchemicals traditionally associated with frothing. RF particle separator10 may further eliminate the need for subsequent panning. As shown inFIGS. 1-2, RF particle separator includes a reservoir, shown as basin20. Basin 20 provides a support structure for various components of RFparticle separator 10. Basin 20 is generally concave shaped, but basin20 may have a variety of different shapes. According to an exemplaryembodiment, basin 20 may be one meter wide, one meter deep, and tenmeters long. According to an exemplary embodiment, basin 20 ismanufactured by removing a portion of ground material. In this form,basin 20 may include a liner material to facilitate retaining fluidswithin basin 20 and have dimensions of one hundred meters wide, threemeters deep, and one hundred meters long. According to an alternativeembodiment, basin 20 is formed from metal, composite, or wood. Accordingto another alternative embodiment, basin 20 is formed from still othersuitable materials.

Referring again to the exemplary embodiment shown in FIGS. 1-2, RFparticle separator 10 may include a carrier fluid, shown as fluid 30.Fluid 30 facilitates the extraction process of RF particle separator 10.Fluid 30 may include a non-homogeneous mixture of differentconstituents, a homogeneous mixture of different constituents, or mayinclude only a single fluid constituent. According to an exemplaryembodiment, fluid 30 may comprise a dielectric fluid (e.g., pure water,water that includes secondary materials, glycerine, furfural, ethyleneglycol, alcohol, solutions of such fluids, etc.). As shown in FIGS. 1-2,fluid 30 is located within basin 20. Fluid 30 may partially or entirelyfill basin 20 as the demands of RF particle separator 10 require.According to an exemplary embodiment, fluid 30 is a liquid. According toan exemplary embodiment, fluid 30 is liquid water. According to analternative embodiment, fluid 30 is an alcohol, acetone, or anotherliquid selected to facilitate the extraction process of RF particleseparator 10.

Referring again to the exemplary embodiment shown in FIGS. 1-2, RFparticle separator 10 includes a material of interest, shown as targetparticles 50. As shown in FIGS. 1-2, target particles 50 may be locatedwithin fluid 30. Target particles 50 may be any material to be separatedfrom fluid 30. Target particles 50 may include valuable minerals. Suchvaluable minerals may constitute the entire target particle 50, ortarget particle 50 may include a valuable mineral and a less valuablematerial (e.g., gangue). According to an exemplary embodiment, targetparticles 50 may comprise valuable metals such as gold, silver, orplatinum, among other valuable metals. According to an alternativeembodiment, target particles 50 may comprise less valuable metals suchas iron, copper, and aluminum, among other less valuable metals. Targetparticles 50 include a specified size. The size of target particles 50may vary based on the nature of previous processing steps. According toan exemplary embodiment, the size of target particles 50 is betweenapproximately 0.1 micrometers to 1.0 millimeters. As shown in FIGS. 1-2,target particles 50 may be suspended within fluid 30. According tovarious alternative embodiments, target particles 50 may be locatedalong the bottom of fluid 30 within basin 20, along a side of fluid 30within basin 20, or randomly oriented within fluid 30.

According to the exemplary embodiment shown in FIGS. 1-2, RF particleseparator 10 may include target particles 50 and extraneous materials,shown as secondary particles 60. Such secondary particles 60 may notrise within fluid 30 to the same extent as target particles 50 onceaffected by field 42. As shown in FIGS. 1-2, secondary particles 60 maybe located within fluid 30. According to an exemplary embodiment,secondary particles 60 include any material within fluid 30 other thantarget particles 50 (e.g. carbon compounds, less valuable materials,etc.). The composition of such secondary particles 60 may includeaggregate, processing chemicals, and materials having a value less thanthe target particles 50. The size and shape of secondary particles varywidely. According to an exemplary embodiment, the size of secondaryparticles 60 is between approximately 0.1 micrometers to 1.0millimeters. As shown in FIGS. 1-2, secondary particles 60 may besuspended within fluid 30. According to various alternative embodiments,secondary particles 60 may be located along the bottom of fluid 30within basin 20, along a side of fluid 30 within basin 20, or randomlyoriented within fluid 30.

According to the exemplary embodiment shown in FIGS. 1-2, the materialproperties of target particles 50 and secondary particles 60 varydepending on the nature of their composition. According to an exemplaryembodiment, the density of target particles 50 is greater than thedensity of fluid 30. Such target particles 50 may nonetheless remainsuspended within fluid 30 due to various flow currents within fluid 30,among other reasons. Flow currents within fluid 30 may occur due to aphysical or thermal movement of fluid 30 within basin 20. According toan alternative embodiment, the density of target particles 50 isapproximately equal to the density of fluid 30. According to stillanother alternative embodiment, the density of target particles 50 isless than the density of fluid 30. Such target particles 50 maynonetheless remain suspended within fluid 30 or sink within fluid 30 dueto various flow currents within fluid 30 or the presence of secondaryparticles 60. By way of example, secondary particles 60 having a greaterdensity than that of target particles 50 may be attached to targetparticles 50 and force them to suspend or sink within fluid 30. Thedensity of secondary particles 60 may similarly be less than, equal to,or greater than the density of fluid 30.

Referring again to the exemplary embodiment shown in FIGS. 1-2, RFparticle separator 10 includes a wave creation device, shown asgenerator 40. Generator 40 is configured to subject fluid 30 to apattern of waves, shown as field 42 having specified characteristics.According to an exemplary embodiment, generator 40 is a wave formgenerator capable of exposing fluid 30 to electromagnetic waves havingidentified properties. Such identified properties may include frequency,intensity, uniformity, direction, polarization, mode shape, and pulselength, among other known properties of electromagnetic waves. The waveform may include a plurality of electromagnetic waves having differentproperties. The plurality of electromagnetic waves may overlap in space,in time, or both in space and in time. Identifying certain properties offield 42 provides greater control of the extraction process of RFparticle separator 10.

According to various alternative embodiments, generator 40 subjectsfluid 30 to a continuous or pulsed field. The electromagnetic fieldwithin the separator may be a standing wave or a non-propagatingevanescent field. Such fields may have a modal character dominatedeither by an electric field component (varying at an RF frequency) or anelectromagnetic field component (varying at an RF frequency). Accordingto an alternative embodiment, generator 40 produces a continuouselectric field component. According to still another alternativeembodiment, generator 40 subjects fluid 30 to an electromagnetic fieldcomponent. Such electromagnetic field may be a continuouselectromagnetic field. According to an alternative embodiment, theelectromagnetic field is a pulsed electromagnetic field. Varying thetype of field 42 generated by generator 40 allows for greater control ofthe extraction process undertaken by RF particle separator 10. By way ofexample, field 42 may be selected as having a predominately magneticfield characteristic in order to extract target particles havingnaturally occurring or introduced magnetic characteristics.

According to the exemplary embodiment shown in FIG. 2, generator 40 maydirect field 42 toward fluid 30. The distance, relative orientation, andpresence of intervening objects between generator 40 and fluid 30 impactthe intensity of the field that affects fluid 30. According to theexemplary embodiment shown in FIGS. 1-2, generator 40 is located on aside of basin 20. It should be understood that generator 40 may belocated in any position with respect to fluid 30, including within fluid30. According to the exemplary embodiment shown in FIG. 2, field 42passes through basin 20 and into fluid 30. According to anotheralternative embodiment, generator 40 is positioned to allow field 42 toflow directly into fluid 30.

Referring next to the alternative embodiment shown in FIG. 3, RFparticle separator 10 may interact with fluid 30. Fluid 30 facilitatesthe extraction process of RF particle separator 10 shown in FIG. 3.Fluid 30 may include various properties as discussed above. According toan exemplary embodiment, RF particle separator 10 includes targetparticles 50. Target particles 50 may comprise valuable or less valuablematerials as discussed above. As discussed above, target particles 50may be located within fluid 30 in various configurations. According toan alternative embodiment, RF particle separator 10 further includessecondary particles 60. Secondary particles 60 may be any material ofvarious sizes within fluid 30, as discussed above, and secondaryparticles 60 may be located within fluid 30 in various configurations.

According to the alternative embodiment shown in FIG. 3, RF particleseparator 10 further includes a transport structure, shown as chute 70.Chute 70 provides a support structure for various components of RFparticle separator 10. According to an exemplary embodiment, chute 70 isgenerally concave shaped, but it should be understood that chute 70 mayhave a variety of different shapes. According to an exemplaryembodiment, chute 70 is manufactured by removing a portion of groundmaterial. In this form, chute 70 may include a liner material tofacilitate retaining fluids within chute 70 and prevent fluid 30 fromseeping into the ground. According to an alternative embodiment, chute70 is formed from a metal, composite, or wood. According to anotheralternative embodiment, chute 70 is formed from still other suitablematerials.

According to the alternative embodiment shown in FIG. 3, chute 70 atleast partially contains fluid 30. Such containment may include chute 70entirely surrounding fluid 30. Fluid 30 may experience a pressurizedstate, depressurized state, or both depending on the operatingconditions of RF particle separator 10. According to an exemplaryembodiment, fluid 30 flows within chute 70 at a specified flow rate. Theflow rate of fluid 30 may be specified according to maximize theextraction process of RF particle separator 10. According to anexemplary embodiment, fluid 30 flows within chute 70 due to gravity.Such flow may occur where a first end of chute 70 is located at agreater elevation than a second end of chute 70. According to analternative embodiment, fluid 30 flows within 70 due to a mechanicalinput. Such mechanical input may include a pump that moves fluid 30within chute 70 at a specified flow rate. According to still anotheralternative embodiment, fluid 30 does not flow within chute 70.

According to an alternative embodiment shown in FIG. 3, chute 70 mayinteract with additional processing equipment. Such processing equipmentmay include milling machines, rock crushers, fluid supplies, and fluidrunoff chutes. According to an exemplary embodiment, chute 70 interactswith a fluid supply that provides unprocessed fluid 30 containing targetparticles 50 into chute 70 for extraction by RF particle separator 10.According to an alternative embodiment, chute 70 is separated from otherprocessing equipment.

Referring again to the alternative embodiment shown in FIG. 3, RFparticle separator 10 further includes a generator 40. Generator 40subjects fluid 30 to a field as discussed above. The number andorientation of generators 40 may be selected based on an operatingcondition of RF particle separator 10 or fluid 30. According to thealternative embodiment shown in FIG. 3, RF particle separator 10includes a plurality of generators 40 spaced at a specified intervalalong chute 70 (e.g., every 1 meter, every 10 meters, etc.). Theposition of generators 40 may be selected in order to facilitatesubjecting fluid 30 to a field. According to an exemplary embodiment,generators 40 may be disposed along a side of chute 70. According tovarious alternative embodiments, generators 40 may be located above,below, within, or on top of fluid 30.

Referring still to the alternative embodiment shown in FIG. 3, with thegenerators 40 engaged, fluid 30 is subjected to a field thereby forminga target zone, shown as subjected portion 44. Subjected portion 44 is aportion of chute 70 where fluid 30 is subjected to a field fromgenerators 40. According to an exemplary embodiment, subjected portion44 extends entirely across chute 70 perpendicular to the flow of fluid30 such that it entirely covers the cross-section of chute 70. As shownin FIG. 3, subjected portion 44 is at least partially defined by alength a along chute 70. According to various alternative embodiments,subjected portion 44 extends radially, spherically, or according toanother defined shape with respect to generators 40.

Referring again to the exemplary embodiment shown in FIG. 3, RF particleseparator 10 may further include an accumulator, shown as recoverysystem 72. Recovery system 72 collects target particles 50 after theyare separated from fluid 30. According to an exemplary embodiment,recovery system 72 may be at least partially coupled to chute 70.According to an alternative embodiment, recovery system 72 may belocated proximate to an external structure, shown as ground surface 22,the top surface of fluid 30, or within fluid 30. According to theexemplary embodiment shown in FIG. 3, recovery system 72 may include astrainer, shown as skimmer 74. Skimmer 74 may be located proximate tothe top surface of fluid 30. Skimmer 74 collects target particles 50located along the top surface of fluid 30. This collection occursthrough contact between target particles 50 and skimmer 74. Targetparticles 50 move to the edge of chute 70. As shown in FIG. 3, recoverysystem 72 further includes a collection point, shown as catch 76. Targetparticles 50 collected by skimmer 74 may be moved to catch 76 forremoval.

Referring again to the exemplary embodiment shown in FIG. 2, targetparticles 50 within fluid 30 may be subjected to electromagnetic field42 created by generator 40. According to an exemplary embodiment, field42 has a predominantly electric field character. Such electric fieldsinclude continuous fields and pulsed electric fields. Field 42 interactswith target particle 50 and increases the temperature of target particle50. According to an exemplary embodiment, the temperature is increaseduniformly throughout the volume of target particle 50. The heatingdepends on the conductivity of target particles 50 multiplied by theelectric field strength squared, which may be a magnetically inducedfield and vary according to the rate of magnetic flux density changesquared (i.e., a higher frequency is better at inducing an electricfield strength value). According to an exemplary embodiment, the targetparticle 50 may comprise a dielectric mineral that is lossy (i.e. thathas a high dielectric loss tangent). Dielectric heating within suchminerals may be due to rotation of polar molecules and may varyaccording to the product of frequency and electric field strengthsquared. According to an alternative embodiment, target particle 50 maycomprise a magnetic material (e.g., a ferromagnetic) that exhibitshysteresis. Magnetic heating within such minerals may be due tovariation in magnetic domains and may vary according to the product offrequency and electromagnetic field strength squared.

As shown in FIGS. 4-5, target particle 50 transfers heat into fluid 30until at least a portion of fluid 30 is vaporized. Vaporizing fluid 30forms a vapor pocket, shown as bubble 52 that is coupled to targetparticle 50 by an interface, shown as contact surface 54. Contactsurface 54 couples bubble 52 to particle 50 through surface tension.This coupling may depend on the wettability of the particle by theliquid fluid. By way of example, vapor bubbles may couple more stronglyto particles having a low liquid wettability. According to the exemplaryembodiment shown in FIGS. 4-5, the density of bubble 52 is lower thanthe density of fluid 30. This difference in density between bubble 52and fluid 30 causes bubble 52 to lift target particle 50 within fluid30. As shown in FIGS. 4-5, the temperature of secondary particle 60 isnot increased sufficiently to vaporize fluid 30. This disparity intemperatures and corresponding variation in attached bubbles 52separates target particles 50 from fluid 30 and most secondary particles60.

Referring again to the exemplary embodiment shown in FIGS. 4-5, bubble52 forms along contact surface 54 of target particle 50. The location ofbubble 52 on target particle 50 may be governed by a number of factors,including the shape, size, and material properties of target particle50, among other factors. According to the exemplary embodiment shown inFIG. 4, bubble 52 forms along an upper portion of target particle 50. Inthis configuration, bubble 52 pulls target particle 50 upwards to thesurface of fluid 30. The lifting force provided by bubble 52 istransferred to target particle 50 through contact surface 54 and causestarget particle 50 to rise. According to the alternative embodimentshown in FIG. 5, bubble 52 is located along a lower portion of targetparticle 50. In this configuration, bubble 52 pushes target particle 50upwards to the surface of fluid 30, and the upper portion of targetparticle 50 may contact another bubble 52 such that it does not furthervaporize fluid 30.

Referring next to the alternative embodiment shown in FIG. 6, field 42increases the temperature of target particle 50 non-uniformly. Field 42may interact with target particle 50 and first increase the temperatureof an outer portion, shown as outer surface 56. As further interactionoccurs, an affected zone, shown as subjected portion 57 of targetparticle 50 extends from outer surface 56 inward to an inner boundary,shown as inner temperature line 58. Subjected portion 57 may include theportion of target particle 50 having an increased temperature. Withinsubjected portion 57, the temperature varies from a higher temperatureat outer surface 56 to a lower temperature at inner temperature line 58.The remaining portion of target particle 50 remains an initialtemperature. The distance between outer surface 56 and inner temperatureline 58 is an affected distance, shown as skin depth _(R) in FIG. 6.

Referring again to the exemplary embodiment shown in FIG. 6,non-uniformly increasing the temperature of target particle efficientlyfacilitates the separation process of the RF particle separator.According to an exemplary embodiment, the diameter of target particles50 is approximately 0.001 meters. With particles of this size,increasing the temperature of subjected portion 57 of target particle 50may provide greater efficiency in part because of the energy savingscaused by increasing the temperature of only part of target particle 50.Efficiency is further promoted because the temperature of subjectedportion 57 may be increased more quickly than a uniform increase of theentire target particle 50. This faster increase in temperature mayreduce the requisite operation time for the field generator and allowsthe RF particle separator to remove more target particles in an equalduration of time.

According to various exemplary embodiments, field 42 includeselectromagnetic waves having a frequency and amplitude. Varying thefrequency of the electromagnetic waves emitted by generator 40 variesskin depth β. According to an exemplary embodiment, skin depth β isinversely proportional to the square root of the frequency of theelectromagnetic waves. By way of example, a higher frequency tends todecrease the skin depth _(R) whereas a lower frequency tends to increasethe skin depth β. According to an exemplary embodiment, skin depth β isapproximately ten percent of the diameter of the target particles 50.According to an alternative embodiment, the skin depth is increaseduntil subjected portion 57 extends throughout target particle. In bothinstances, the efficiency of RF particle separator 10 is increasedrelative to embodiments where the skin depth is substantially largerthan the size of the particle (or its mineral portion). The skin depthimpacts the size of particles moved by RF particle separator 10. Thefrequency of field 42 may then be varied in order to remove differentsized particles with each applied frequency. According to an exemplaryembodiment, the frequency of the field is increased or decreasedaccording to a specified pattern thereby allowing for the extraction ofcertain sized particles.

Referring next to the alternative embodiment shown in FIG. 7, targetparticles 50 may be extracted from fluid 30 without vaporizing fluid 30.As shown in FIG. 7, field 42 increases the temperature of targetparticle 50 according to a specified pattern, shown as thermal gradient112. According to an exemplary embodiment, field 42 includeselectromagnetic waves having a frequency, amplitude, and othercharacteristics.

According to an exemplary embodiment, the frequency of theelectromagnetic waves within field 42 varies. Such variance may occur ina single linear dimension (e.g., vertically, laterally, along a depth,etc.), a single curvilinear dimension, two dimensions formed by two ofthe foregoing linear or curvilinear dimensions, spherically, oraccording to some other one, two, or three dimensional geometry.According to an alternative embodiment, the amplitude of theelectromagnetic waves within the field varies. According various otheralternative embodiments, still other characteristics of the field vary.

According to the exemplary embodiment shown in FIG. 7, target particles50 within fluid 30 interact with field 42. Variance among theelectromagnetic waves within field 42 provides a non-uniform temperatureincrease within target particles 50. According to the exemplaryembodiment shown in FIG. 7, the frequency or amplitude ofelectromagnetic waves of field 42 varies across the particles, andheating due to electromagnetic waves acting on the bottom 110 of targetparticle 50 may be greater than the heating due to electromagnetic wavesacting on the top 111 of target particle 50. This variance in heatingresults in thermal gradient 112 within target particle 50. As discussedabove, thermal gradient 112 is related to the variance incharacteristics of field 42. The material properties of target particles50 (e.g., density, thermal conductivity, presence of trace materials,etc.) may impact the degree that thermal gradient 112 corresponds to thevariance within the electromagnetic waves of field 42.

Referring again to the exemplary embodiment shown in FIG. 7, field 42interacts with target particle 50 to increase the temperature of targetparticle 50. The temperature is increased to a first specified level,shown as first temperature 114 at a location proximate to the bottom oftarget particle 50 and a second specified level, shown as secondtemperature 116 at a location proximate to the top of target particle50. According to an exemplary embodiment, first temperature 114 ishigher than second temperature 116. While the entire target particle 50transfers heat to fluid 30, portions of target particle 50 having aproportionally higher temperature transfer proportionally more heat tothe surrounding fluid 30. According to an alternative embodiment, field42 creates thermal gradient 112 having lateral characteristics such thattarget particle 50 moves laterally within fluid 30.

Referring still to the exemplary embodiments shown in FIG. 7, theadditional heat transfer proximate to certain portions of targetparticle 50 causes a greater increase in the temperature of fluid 30along to the bottom of target particle 50 than the fluid 30 along to thetop of target particle 50. The warmer fluid 30 proximate to the bottomof target particle 50 expands and rises toward the surface of fluid 30.This rising fluid 30 causes a thermal influx, shown as propulsioncurrents 118. Propulsion currents 118 interact with the surface oftarget particles 50 to provide a lifting force. According to analternative embodiment, field 42 causes different thermal gradients 112within target particles 50. These varying thermal gradients 112 causeunique heat transfer between target particles 50 and fluid 30 andprovide for different movement of target particles 50.

Referring next to still another alternative embodiment shown in FIG. 8,target particles 50 may be moved through magnetic interaction. Accordingto an exemplary embodiment, target particles 50 may comprise aconductive material capable of carrying an electric current. Field 42created by generator 40 may interact with target particles 50 along aspecified direction, shown as field vector 120. Field vector 120 maycause eddy currents to form and circulate within target particles 50perpendicular to field vector 120. These eddy currents may travelthroughout or only within a certain volume of target particles 50. Flowof electrons along the electrical circuit may induce a voltage andelectromagnetic field within target particles 50. This electromagneticfield may combine with field 42 having a specified gradient and interactwith the current to produce a J×B force, shown as force vector 122having a magnitude and a direction. The magnitude of force vector 122moves target particles 50 along the direction of force vector 122. Suchmovement of target particles 50 through fluid 30 caused by force vector122 is less dependent on the characteristics of fluid 30 thanalternative methods such as vaporizing fluid 30.

Referring again to the exemplary embodiment shown in FIG. 8, severalfactors impact the magnitude of force vector 122. By way of example, themagnitude of waves within field 42 and the conductance of targetparticles 50, among other factors, impact the magnitude of force vector122. According to an exemplary embodiment, target particles 50 may behighly conductive materials (gold, silver, copper, etc.). Highlyconductive materials allow field 42 to induce stronger eddy currentswithin target particles 50 and may increase the magnitude of forcevector 122. A stronger induction of eddy currents within targetparticles 50 may further facilitate the separation operation of RFparticle separator 10 because secondary particles 60 may be a materialnot suitable to carrying eddy currents or may be a material lesssuitable to carrying eddy currents than target particles 50. By way ofexample, aggregate material may be not well suited to carrying eddycurrents. Aggregates failing to carry sufficient eddy currents will notmove substantially in the direction of force vector 122. Targetparticles 50 may be better at carrying eddy currents than secondaryparticles 60 and may move in the direction of force vector 122 while thesecondary particles 60 may not.

According to an alternative embodiment, the target particles may have aconductance lower than highly conductive materials but greater than thesecondary particles (e.g., titanium, platinum, etc.). As discussedabove, the strength of the field may also impact the magnitude of aforce vector. The strength of the field may be controlled in order toinduce eddy currents within the target particles that create asufficient magnitude of a force vector. According to an exemplaryembodiment, the magnitude of a force vector may be sufficient where itis capable of moving the target particles along a specified path.

According to an alternative embodiment, the strength of the field may befurther increased in order to create a force vector having a magnitudecapable of moving the target particles faster or slower, as conditionsmay require. By way of example, a larger force may be necessary wherethe fluid is flowing rapidly or where the target particles must beextracted from the fluid quickly. Under these circumstances, therequisite force vector may have a magnitude much greater than the weightforce of the target particle. According to an exemplary embodiment, thestrength of the field is controlled to induce a force vector capable ofmoving the target particles without substantially moving the secondaryparticles.

According to an alternative embodiment, the target particles may havemagnetic properties apart from those paramagnetically induced by afield. Such magnetic properties may have been introduced to targetparticles or naturally occurring within the target particles. Themagnetic properties may be induced by the field but be nonlinear anddependent upon the amplitude or frequency of the field. Ferrousmaterials may be particularly susceptible to such properties. Accordingto an exemplary embodiment, the target particles may be iron havingnaturally occurring magnetic properties. According to an alternativeembodiment, target particles may be iron having introduced magneticproperties. The introduction of magnetic properties may occur throughvarious known techniques including introducing the target particles to amagnetic material or an electromagnet. Naturally occurring or introducedmagnetic properties of the target particles further interact with theapplied electromagnetic field and create a larger force than similartarget particles exposed to a similar electromagnetic field.

According to an alternative embodiment, the target particles may becharged. Charged target particles interact with an electromagnetic fieldand experience a Lorentz force acting to move the particle.Electromagnetic fields include an electric field portion, E and anelectromagnetic field portion, B. For a particle having a given electriccharge, q, the force acting to move the particle is the charge qmultiplied by the applied electric field and the cross product of thevelocity of the particle and the applied electromagnetic field. Thecross product causes the Lorentz force to act perpendicular to both thevelocity with applied electromagnetic field. According to an exemplaryembodiment, the target particles may be naturally charged. According toan alternative embodiment, the target particles may be charged prior toentering the field. Such charging may occur or according to variousknown methods, including electrostatically charging the target particlesor creating ions by exposing the target particles to a chemicalcompound.

Referring next to the exemplary embodiment shown in FIGS. 9-10, RFparticle separator 10 may further include a fluid characteristicregulator, shown as conditioner system 80. Conditioner system 80 maydecrease the air pressure above fluid 30 in order to facilitate the sizeor formation rate of bubbles 52 within fluid 30. According to theexemplary embodiment shown in FIGS. 9-10, conditioner system 80 mayfurther include a cover, shown as housing 82. Housing 82 may include aninside portion and an outside portion and partially or entirely surroundfluid 30 thereby sealing fluid 30 from external atmospheric pressureconditions.

According to the exemplary embodiment shown in FIG. 9, housing 82 may bedisc shaped and coupled to a surface of basin 20. Such coupling may beaccomplished according to any known technique including welding, abolted connection, using an adhesive, or other known couplingtechniques. According to the alternative embodiment shown in FIG. 10,housing 82 is partially coupled to ground surface 22. Such coupling mayoccur by burying a portion of housing 82 within ground surface 22, byusing seal connection, or by various alternative known methods.

According to the exemplary embodiment shown in FIGS. 9-10, conditionersystem 80 may further include a volume, shown as zone 84. Zone 84 isformed between the surface of fluid 30 and the inside portion of housing82. According to an exemplary embodiment, zone 84 may be filled with afluid and substantially sealed from external atmospheric conditions.Such a fluid may include air, argon gas, or another known fluid capableof facilitating to the formation of bubbles 52 within fluid 30. Sealingzone 84 may provide at least the benefit of allowing for the regulationof certain fluid conditions within zone 84. Such certain fluidconditions may include temperature, pressure, among other knownconditions of the fluid within zone 84.

According to the exemplary embodiment shown in FIGS. 9-10, zone 84 is influid communication with fluid 30. As shown in FIGS. 9-10, the fluidpressure within zone 84 acts on fluid 30 and inhibits the formation ofbubbles 52. Further, the heat energy of the fluid within zone 84 may beabsorbed by fluid 30 or the fluid within zone 84 may absorb heat energyfrom fluid 30. According to various alternative embodiments, additionalcharacteristics of the fluid within zone 84 impact characteristics offluid 30.

According to the exemplary embodiment shown in FIG. 9, conditionersystem 80 includes a pressure regulating device, shown as pump 86.According to the exemplary embodiment shown in FIG. 9, pump 86 may becoupled to housing 82. According to an alternative embodiment, pump 86may be coupled to basin 20. Varying the coupling location of pump 86 mayvary a pressure profile across zone 84 whereby the pressure above oneportion of fluid 30 may be greater or lower than the pressure above adifferent portion of fluid 30. According to an exemplary embodiment,conditioner system 80 further includes one or more diffusers that allowpump 86 to more uniformly increase or decrease the pressure within zone84.

According to the exemplary embodiment shown in FIG. 9, pump 86 isconfigured to decrease the pressure of the fluid within zone 84 relativeto the atmospheric conditions outside housing 82. Reducing the pressureof the fluid within zone 84 provides at least the benefit of changingthe force acting upon fluid 30 by the fluid within zone 84. As discussedabove, this force acting upon fluid 30 resists the formation of bubbles52. Reducing the force acting on fluid 30 allows bubbles 52 to formwithin fluid 30 more easily. According to an alternative embodiment,pump 86 is configured to increase the pressure of the fluid within zone84 relative to the atmospheric pressure outside housing 82. Such anincrease in pressure may be necessary in order to allow RF particleseparator 10 to selectively remove target particles 50 from fluid 30 orprevent excessive vaporization of fluid 30.

Referring further to the exemplary embodiment shown in FIG. 9, thetemperature of fluid 30 may be sufficiently high to vaporize fluid 30under the surrounding atmospheric conditions. This effect may especiallyoccur in areas of greater elevation where the atmospheric pressure islower than at sea-level. Under such conditions, fluid 30 may begin tovaporize uncontrollably and cause RF particle separator 10 to extractboth target particles 50 and secondary particles 60 from fluid 30. Thisplural extraction is not preferred in that a mixture may require furtherprocessing in order to separate target particles 50 from the extractedmixture of target particles 50 and secondary particles 60. According toan alternative embodiment, pump 86 may be configured to increase thepressure within zone 84 thereby preventing this uncontrolledvaporization condition.

According to various alternative embodiments, other conditions of thefluid within a zone surrounding the carrier fluid may be regulated.According to an exemplary embodiment, a conditioner system may include atemperature regulating device, such as a heater or air conditioner. Aheater or air conditioner in fluid communication with the fluidsurrounding the carrier fluid may be necessary in order to facilitatethe extraction of target particles from the carrier fluid. By way ofexample, the temperature of the fluid surrounding the carrier fluid maybe regulated in order to prevent the fluid containing target andsecondary particles from changing state.

According to an alternative embodiment, the conditioner system mayinclude an air conditioner that reduces the temperature of fluidsurrounding the carrier fluid. As discussed above, the temperature ofthe carrier fluid under certain atmospheric conditions (e.g., lowpressure, etc.) may lead to uncontrolled vaporization and cause the RFparticle separator to extract both target and secondary particles.Uncontrolled vaporization may be avoided by increasing the pressure ofthe fluid acting on the carrier fluid. Such uncontrolled boiling mayfurther be avoided by reducing the temperature of the fluid surroundingthe carrier fluid thereby causing heat transfer from the carrier fluidinto the surrounding fluid. An air conditioner or heat pump that reducesthe temperature of a surrounding fluid may reduce the temperature of thecarrier fluid until the uncontrolled vaporization condition (i.e. themaximum temperature of the carrier fluid before vaporization occurs at agiven pressure) is no longer present.

According to an alternative embodiment, the conditioner system mayinclude a heating element that increases the temperature of fluidsurrounding the carrier fluid. An increased temperature of thesurrounding fluid may increase the temperature of the carrier fluidthrough heat transfer from the surrounding fluid to the carrier fluid.Such an increase may be necessary in order to prevent the carrier fluidfrom freezing due to cold atmospheric conditions, for example.Preventing the carrier fluid from freezing provides at least the benefitof allowing bubbles to extract target particles from the carrier fluid.Should a portion of the carrier fluid freeze, bubbles will not lifttarget particles to the surface of the carrier fluid for separation.Separation may not be possible for at least the reason that a separatormay not have physical access to the target particles due to physicalseparation by a frozen layer of carrier fluid. Separation may furthernot be possible due to frozen carrier fluid interfering with theoperation of the separator in another way (i.e. preventing the movementof various components).

While the preceding discussion of the conditioner system includedreferences to various components of RF particle separator 10 accordingto an exemplary embodiment shown in FIGS. 9-10, it should be understoodthat the conditioner system may be configured to interact with variousalternative embodiments of the RF particle separator. Such alternativeembodiments may include the RF particle separator shown in FIG. 3, amongothers. Still further orientations and configurations of the conditionersystem may be possible and understood by an ordinary person in therelevant art.

Referring next to the exemplary embodiment shown in FIG. 11, RF particleseparator 10 may further include a fluid regulation system, shown asgovernor 90. Governor 90 may adjust a condition of fluid 30. Accordingto the exemplary embodiment shown in FIG. 11, governor 90 may be coupledto an upper portion of basin 20 above fluid 30. According to variousalternative embodiments, governor 90 may be coupled with another portionof basin 20 above fluid 30, coupled with basin 20 partially within fluid30, or coupled with basin 20 entirely submerged within fluid 30. Suchcoupling may occur through a variety of known techniques (adhesive,bolted connection, snap fitting, etc.). According to still otheralternative embodiments, governor 90 may be coupled to another portionof RF particle separator 10 or may float within or upon fluid 30.

According to the exemplary embodiment shown in FIG. 11, governor 90 mayfurther include a substance capable of varying a property of fluid 30,shown as substance 100. Substance 100 may be a fluid or a solid capableof being dispensed in various ways. According to an exemplaryembodiment, substance 100 is a liquid (e.g., acetone, etc.). Such liquidsubstance 100 may be sprayed, dropped, or otherwise infused into fluid30. According to an alternative embodiment, substance 100 is a solidmaterial. Such solid substance 100 may be introduced into fluid 30 as asingular amount of substance 100 or may be introduced into fluid 30 asmultiple particles of substance 100. According to still anotheralternative embodiment, substance 100 is a gas. Gaseous substance 100may dissolve within fluid 30 or may remain dissociated from fluid 30 toregulate a condition of fluid 30. Substances 100 may dissolve or mixwithin fluid 30 at a specified release rate. The release rate ofsubstance 100 may be specified based on various conditions of fluid 30including flow rate, temperature, and pressure, among other conditionsof fluid 30 or the surrounding environment.

According to the exemplary embodiment shown in FIG. 11, substance 100regulates the vapor pressure of fluid 30. Adjusting the vapor pressureof fluid 30 provides at least the benefit of facilitating or inhibitingthe formation of bubbles 52 within fluid 30. Fluid 30 includes aninitial vapor pressure before substance 100 is added. By way of example,the vapor pressure of pure water at twenty-five degrees C. is 0.03atmospheres. This initial vapor pressure of may be increased ordecreased as the conditions of fluid 30 demand. By way of example, thevapor pressure of fluid 30 may be increased to facilitate the formationof bubbles 52 or may be decreased to inhibit the formation of bubbles52.

According to the alternative embodiment shown in FIG. 11, substance 100regulates the surface tension of liquid fluid 30. The surface tension offluid 30 is ability of the liquid fluid 30 to resist an external forcecaused by cohesion of similar molecules. Fluid 30 includes an initialsurface tension before substance 100 is added. By way of example, thesurface tension of pure water at twenty-five degrees C. is 71.97 dynesper cubic centimeter. This surface tension may be increased or decreaseddepending on the operating conditions of RF particle separator 10. Byway of example, liquid fluid 30 may be water and substance 100 may beethanol. The surface tension of a combination of water and forty percentethanol by weight at twenty-five degrees C. is 29.63 dynes per cubiccentimeter. According to an exemplary embodiment, substance 100 mayincrease the surface tension of fluid 30 to reduce the size andformation rate of bubbles 52 within fluid 30. According to analternative embodiment, substance 100 may decrease the surface tensionof fluid 30 to increase the size and formation rate of bubbles 52 withinfluid 30.

According to the alternative embodiment shown in FIG. 11, the substanceregulates the latent heat of fusion or the latent heat of vaporizationof the carrier fluid. According to an exemplary embodiment, thesubstance may include a saline solution or crystalline salt. The carrierfluid having a saline solution or crystalline salt added may freeze at alower temperature than an untreated carrier fluid and not experience thefreezing issues discussed above. According to an alternative embodiment,the substance may cause the carrier fluid to vaporize at a differenttemperature than an untreated carrier fluid and prevent the uncontrolledvaporization issues discussed above.

Referring still to the exemplary embodiment shown in FIG. 11, governor90 may further include a distributor, shown as dispenser 95. As shown inFIG. 11, dispenser 95 may be configured to facilitate the transmissionof substance 100 into fluid 30. According to the exemplary embodimentshown in FIG. 11, dispenser 95 is coupled to basin 20 above a level offluid 30. According to various alternative embodiments, dispenser 95 maybe coupled to another component of RF particle separator 10 and may bedisposed within fluid 30.

According to the exemplary embodiment shown in FIG. 11, the physicalstructure of dispenser 95 may be related to a characteristic ofsubstance 100. As shown in FIG. 11, dispenser 95 may be an auger systemcapable of facilitating the transmission of a solid bead shapedsubstance 100 into fluid 30. Dispenser 95 may include a hopperconfigured to store substance 100 and a screw device that interacts withsubstance 100 and facilitate the transmission of substance 100 intofluid 30. Dispenser 95 may further include a mixer that facilitatescreating a solution of substance 100 and fluid 30. While a specificconfiguration is disclosed, it should be understood that dispenser 95may further include various additional components configured tomanipulate substance 100 either prior to or after substance 100 isintroduced into fluid 30.

According to an alternative embodiment, the dispenser may be a nozzlesystem capable of facilitating the transmission of a fluid substanceinto the carrier fluid. The dispenser may include a tank configured tostore the fluid substance and a nozzle that regulates the flow of thefluid substance. The dispenser may further include a mixer thatfacilitates creating a solution of the fluid substance and carrierfluid. While a specific configuration is disclosed, it should beunderstood that the dispenser may further include various additionalcomponents configured to manipulate the substance either prior to orafter the substance is introduced into the carrier fluid.

Referring still to the exemplary embodiment shown in FIG. 11, governor90 may further include a substance manager, shown as controller 97. Asshown in FIG. 11, controller 97 is configured to activate dispenser 95in order to direct substance 100 into fluid 30. Controller 97 mayinclude one or more processing circuits and memory devices configured toactivate dispenser 95 in a specified manner. Such specified manner mayinclude a continuous operation mode, a timer operation mode, or anas-needed operation mode.

According to the exemplary embodiment shown in FIG. 11, controller 97further includes a sensor configured to monitor a condition of fluid 30.Controller 97 may then activate dispenser 95 in response to a receivedsignal from the sensor in order to change a condition of fluid 30. Byway of example, controller 97 may monitor the surface tension of fluid30 either directly or indirectly and adjust the activation of dispenser95 in order to change a condition of fluid 30. According to variousalternative embodiments, controller 97 may adjust the activation ofdispenser 95 in response to another received condition (e.g., thetemperature or pressure, among other conditions, of the fluid withinzone 84, the temperature and pressure, among other conditions, of theambient environment, etc.).

According to an alternative embodiment, controller 97 may activatedispenser 95 in a timer mode according to a predetermined schedule.Timer mode operation may be appropriate where the conditions of fluid 30vary predictably over time or do not substantially vary with time. Suchtimer mode operation provides at least the benefit of limiting thenumber of additional sensors or components needed to regularly activatedispenser 95. A predetermined schedule may be programmed by a user intocontroller 97 or may be calculated by controller 97. By way of example,a user may input a time duration of one minute into controller 97thereby causing controller 97 to activate dispenser 95 once everyminute.

According to still another alternative embodiment, controller 97 mayactivate dispenser 95 continuously. Such continuous operation may benecessary where the conditions of fluid 30 require a constant release ofthe regulating substance. By way of example, a constant release of theregulating substance may be necessary where the ambient temperaturesurrounding the carrier fluid is very low. As discussed above, theseconditions may cause the carrier fluid to freeze and prevent effectiveseparation of the target particles from the carrier fluid.

Referring next to the alternative embodiment shown in FIG. 12, RFparticle separator 130 may be a mobile unit configured to extract targetparticles from fluid 30. As shown in FIG. 12, RF particle separator 130includes a collector, shown as accumulator 132 and a support, shown asstructure 134. According to an exemplary embodiment, structure 134 isgenerally flat and may float upon a portion of fluid 30 to facilitatethe extraction operation of RF particle separator 130.

According to the exemplary embodiment shown in FIG. 12, RF particleseparator 130 further includes generator 40. As discussed above,generator 40 is configured to subject fluid 30 to a field havingspecified characteristics. Such interaction causes target particles torise as discussed above. According to an exemplary embodiment, generator40 is a wave form generator capable of subjecting fluid 30 to anelectromagnetic wave having identified properties (e.g., frequency,intensity, uniformity, direction, etc.). Identifying certain propertiesof the electromagnetic field provides greater control of the extractionprocess of RF particle separator 130.

Referring still to the exemplary embodiment shown in FIG. 12, RFparticle separator 130 may include a collector, shown as accumulator132. Accumulator 132 is configured to gather target particles 50 raisedwithin fluid 30 by generator 40 and deposit them into a catch (notshown). According to an exemplary embodiment, accumulator 132 mayinclude a skimmer that contacts fluid 30 and extracts target particles50 from fluid 30. Such a skimmer may include a fixed blade design thatmoves within fluid 30 and contacts target particles 50. By way ofexample, an angled fixed blade design may cause target particles 50 tomove along the blade and into the catch. According to an alternativeembodiment, accumulator 132 may include a driven skimmer device thatmoves within fluid 30 independent of any movement of structure 134within fluid 30. According to still another alternative embodiment,accumulator 132 includes a suction device capable of extracting targetparticles raised by generator 40 from fluid 30.

According to the exemplary embodiment shown in FIG. 12, RF particleseparator 130 is configured to move with respect to fluid 30. Suchmovement may include drifting or driven motion within basin 20 along thesurface of fluid 30. As RF particle separator 130 moves with respect tofluid 30, generator 40 subjects fluid 30 to a field that extracts targetparticles 50. The movement between RF particle separator 130 and fluid30 may allow RF particle separator 130 having an extraction profile toextract target particles 50 from fluid 30 located within basin 20 havinga size larger than the extraction profile of RF particle separator 130.

According to an exemplary embodiment, the carrier fluid flows within abasin along a specified path and RF particle separator 130 moves withina current generated by the carrier fluid. According to an alternativeembodiment, RF particle separator 130 further includes a driving deviceconfigured to move RF particle separator 130 within the carrier fluid.Such movement may occur along the surface of the carrier fluid or mayoccur within the carrier fluid. RF particle separator 130 may furtherinclude a controller configured to regulate the movement of RF particleseparator 130 within the carrier fluid. Such regulated movement mayinclude a specified path or a random pattern having specified operationparameters.

It is important to note that the construction and arrangement of theelements of the systems and methods as shown in the exemplaryembodiments are illustrative only. Although only a few embodiments ofthe present disclosure have been described in detail, those skilled inthe art who review this disclosure will readily appreciate that manymodifications are possible (e.g., variations in sizes, dimensions,structures, shapes and proportions of the various elements, values ofparameters, mounting arrangements, use of materials, colors,orientations, etc.) without materially departing from the novelteachings and advantages of the subject matter recited. For example,elements shown as integrally formed may be constructed of multiple partsor elements. It should be noted that the elements and/or assemblies ofthe enclosure may be constructed from any of a wide variety of materialsthat provide sufficient strength or durability, in any of a wide varietyof colors, textures, and combinations. Additionally, in the subjectdescription, the word “exemplary” is used to mean serving as an example,instance or illustration. Any embodiment or design described herein as“exemplary” is not necessarily to be construed as preferred oradvantageous over other embodiments or designs. Rather, use of the wordexemplary is intended to present concepts in a concrete manner.Accordingly, all such modifications are intended to be included withinthe scope of the present inventions. The order or sequence of anyprocess or method steps may be varied or re-sequenced according toalternative embodiments. Any means-plus-function clause is intended tocover the structures described herein as performing the recited functionand not only structural equivalents but also equivalent structures.Other substitutions, modifications, changes, and omissions may be madein the design, operating conditions, and arrangement of the preferredand other exemplary embodiments without departing from scope of thepresent disclosure or from the spirit of the appended claims.

The present disclosure contemplates methods, systems and programproducts on any machine-readable media for accomplishing variousoperations. The embodiments of the present disclosure may be implementedusing existing computer processors, or by a special purpose computerprocessor for an appropriate system, incorporated for this or anotherpurpose, or by a hardwired system. Embodiments within the scope of thepresent disclosure include program products comprising machine-readablemedia for carrying or having machine-executable instructions or datastructures stored thereon. Such machine-readable media can be anyavailable media that can be accessed by a general purpose or specialpurpose computer or other machine with a processor. By way of example,such machine-readable media can comprise RAM, ROM, EPROM, EEPROM, CD-ROMor other optical disk storage, magnetic disk storage or other magneticstorage devices, or any other medium which can be used to carry or storedesired program code in the form of machine-executable instructions ordata structures and which can be accessed by a general purpose orspecial purpose computer or other machine with a processor. Wheninformation is transferred or provided over a network or anothercommunications connection (either hardwired, wireless, or a combinationof hardwired or wireless) to a machine, the machine properly views theconnection as a machine-readable medium. Thus, any such connection isproperly termed a machine-readable medium. Combinations of the above arealso included within the scope of machine-readable media.Machine-executable instructions include, for example, instructions anddata which cause a general purpose computer, special purpose computer,or special purpose processing machines to perform a certain function orgroup of functions.

Although the figures may show a specific order of method steps, theorder of the steps may differ from what is depicted. Also two or moresteps may be performed concurrently or with partial concurrence. Suchvariation will depend on the software and hardware systems chosen and ondesigner choice. All such variations are within the scope of thedisclosure. Likewise, software implementations could be accomplishedwith standard programming techniques with rule based logic and otherlogic to accomplish the various connection steps, processing steps,comparison steps and decision steps.

What is claimed:
 1. A method of separating a mineral bearing particlefrom a fluid, comprising: providing a housing along a surface of thefluid; moving the housing along the surface of the fluid with a driver;and applying a radio-frequency electromagnetic field to the fluid with agenerator, wherein applying the radio-frequency electromagnetic fieldincludes increasing a temperature of the mineral bearing particlecontained within the fluid to a boiling point of the fluid whereby themineral bearing particle transfers heat into the fluid.
 2. The method ofclaim 1, further comprising floating the housing along the surface ofthe fluid.
 3. The method of claim 1, wherein applying theradio-frequency electromagnetic field includes increasing thetemperature of the mineral bearing particle within a region defined byan outer surface of the mineral bearing particle and extending inward toa specified skin depth.
 4. The method of claim 1, further comprisingboiling the fluid to form a plurality of vapor bubbles within the fluidat a formation rate.
 5. The method of claim 4, further comprising movingthe mineral bearing particle through the fluid with the plurality ofvapor bubbles.
 6. The method of claim 1, wherein applying theradio-frequency electromagnetic field includes increasing thetemperature of the mineral bearing particle homogeneously.
 7. The methodof claim 1, wherein the radio-frequency electromagnetic field includes aspecified wave form.
 8. The method of claim 1, the fluid defining afirst fluid, further comprising varying a condition of a second fluidwith a regulator, the second fluid disposed adjacent the first fluid. 9.The method of claim 8, wherein varying the condition of the second fluidincludes at least partially surrounding the first fluid with a case ofthe regulator.
 10. The method of claim 9, wherein varying the conditionof the second fluid includes varying a pressure of the second fluidwithin the case with a pressure controller.
 11. The method of claim 10,wherein the pressure controller includes a piston pump.
 12. The methodof claim 1, further comprising adjusting a heating characteristicassociated with the mineral bearing particle by varying a parameter ofthe radio-frequency electromagnetic field with a controller.
 13. Themethod of claim 12, further comprising varying the parameter of theradio-frequency electromagnetic field based on a specified target unitsize for the mineral bearing particle.
 14. The method of claim 13,wherein the heating characteristic is a specified skin depth.
 15. Themethod of claim 13, wherein the heating characteristic is a specifiedthermal gradient.
 16. The method of claim 12, further comprising varyingthe parameter of the radio-frequency electromagnetic field based on aspecified target unit density for the mineral bearing particle.
 17. Themethod of claim 16, wherein the heating characteristic is a specifiedskin depth.
 18. The method of claim 16, wherein the heatingcharacteristic is a specified thermal gradient.
 19. A method forseparating a mineral bearing particle from a fluid, comprising:providing a housing; containing the fluid within the housing, the fluidcontaining the mineral bearing particle; applying a radio-frequencyelectromagnetic field to the mineral bearing particle using a generator;and increasing a temperature of a portion of the mineral bearingparticle with the radio-frequency electromagnetic field, wherein themineral bearing particle transfers heat into the fluid to produce aheated fluid, the heated fluid imposing motion-inducing forces on themineral bearing particle.
 20. The method of claim 19, further comprisingdifferentially sorting the mineral bearing particle by at least one ofsize and density, wherein differentially sorting the mineral bearingparticle by at least one of size and density includes varying a fieldintensity of the radio-frequency electromagnetic field.
 21. The methodof claim 19, further comprising resistively heating the mineral bearingparticle with the radio-frequency electromagnetic field to generate aspecified temperature gradient.
 22. The method of claim 19, furthercomprising heating the mineral bearing particle by magnetic hysteresiswith the radio-frequency electromagnetic field to generate a specifiedtemperature gradient.
 23. The method of claim 19, further comprisingdielectrically heating the mineral bearing particle with theradio-frequency electromagnetic field to generate a specifiedtemperature gradient.
 24. The method of claim 19, further comprisingboiling the fluid to form a plurality of vapor bubbles within the fluidat a formation rate.
 25. The method of claim 24, further comprisingmoving the mineral bearing particle through the fluid with the pluralityof vapor bubbles.
 26. A method for separating a mineral bearing particlefrom a fluid, comprising: providing a housing; containing the fluidwithin the housing, the fluid containing the mineral bearing particle;applying a non-uniform radio-frequency field to the mineral bearingparticle using a generator; and moving the mineral bearing particlewithin the fluid with a propulsion force induced by the non-uniformradio-frequency field.
 27. The method of claim 26, further comprisingmoving the mineral bearing particle at least one of laterally,vertically, and rotationally within the fluid.
 28. The method of claim26, further comprising differentially sorting the mineral bearingparticle by size, wherein differentially sorting the mineral bearingparticle by size includes varying a field intensity of the non-uniformradio-frequency field.
 29. The method of claim 26, wherein moving themineral bearing particle includes inducing a plurality of currentswithin the mineral bearing particle to generate a force produced byinteraction of the plurality of currents with a magnetic component ofthe non-uniform radio-frequency field.
 30. The method of claim 29,wherein moving the mineral bearing particle includes generating agradient in the force applied to the mineral bearing particle.
 31. Themethod of claim 29, wherein applying the non-uniform radio-frequencyfield includes applying a specified wave form.
 32. The method of claim31, wherein the specified wave form comprises a continuous wave having aspecified frequency and a specified intensity.
 33. The method of claim31, wherein the specified wave form comprises a pulsed electromagneticfield, wherein the pulsed electromagnetic field includes a gradient anda field strength.
 34. The method of claim 31, wherein the specified waveform comprises a continuous electromagnetic field, wherein thecontinuous electromagnetic field includes a gradient and a fieldstrength.
 35. The method of claim 31, wherein applying the specifiedwave form includes differentially manipulating the mineral bearingparticle.